Tertiary content addressable memory based motion estimator

ABSTRACT

Presented herein are Tertiary Content Addressable Memory based motion estimator(s). In one embodiment, there is presented a method for encoding a picture. The method comprises storing a reference picture in a memory; taking samples from at least one line of a prediction block, wherein each of the samples comprises a plurality of bits, the plurality of bits comprising most significant bits and least significant bits; concatenating the samples; replacing the least significant bits of the samples with “don&#39;t cares”, thereby generating at least one data word; addressing the memory with the at least one data word; receiving one or more addresses, said one or more addresses associated with one or more blocks; replacing a portion of the “don&#39;t cares” with a portion of the least significant bits of the samples, thereby generating another one or more data words; and addressing the memory with the another one or more data words.

RELATED APPLICATIONS

This application is related to the following applications:

-   (1) “Tertiary Content Addressable Memory Based Motion Estimator,” a     non-provisional application for U.S. patent Ser. No. ______,     (Attorney Docket No. 15927US01) filed Jul. 30, 2004 by Gaurav     Aggarwal, et al. -   (2) “Tertiary Content Addressable Memory Based Motion Estimator,” a     non-provisional application for U.S. patent Ser. No. ______,     (Attorney Docket No. 15928US01) filed Jul. 27, 2004 by Gaurav     Aggarwal, et al.

Each of which are incorporated herein by reference.

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

[Not Applicable]

[MICROFICHE/COPYRIGHT REFERENCE]

[Not Applicable]

BACKGROUND OF THE INVENTION

Video encoding standards such as MPEG-2, ITU-H.264 (also known as MPEG-4, Part 10 and Advanced Video Coding) use motion compensation for compressing video data comprising a series of pictures. Motion compensation predicts a predicted picture from one or more reference pictures.

An encoder predicts a predicted picture by dividing the picture into smaller blocks of pixels. The encoder then searches pixels from the reference picture(s) for a similar block, known as a reference block. An identification of the reference block and the difference between the reference block and the predicted block, known as the prediction error, represent the predicted block.

Identification of the similar block in the reference picture is known as motion estimation. A memory stores the reference picture. The motion estimator searches the memory for a block that is similar to the reference block.

Motion estimation can potentially use a very large number of memory accesses for determining a reference picture. A high definition television (HDTV) video comprises 30 1920×1080 pixel pictures per second, for example. A common block size can be, for example, a 16×16 block of pixels, Therefore, an exhaustive search may not be practical, especially for encoding in real time.

In one approach, the encoder may take a smaller number of samples of the block that are preferably sparsely scattered about the block. The motion estimator can then search the reference picture for the samples of the block. Although the foregoing may be faster than an exhaustive search, this can also be time-consuming and computationally intense.

Further limitations and disadvantages of conventional and traditional approaches will become apparent to one of ordinary skill in the art through comparison of such systems with the present invention as set forth in the remainder of the present application with reference to the drawings.

BRIEF SUMMARY OF THE INVENTION

Presented herein are Tertiary Content Addressable Memory based motion estimator(s).

In one embodiment, there is presented a method for encoding a picture. The method comprises storing a reference picture in a memory; taking samples from at least one line of a prediction block, wherein each of the samples comprises a plurality of bits, the plurality of bits comprising most significant bits and least significant bits; concatenating the samples; replacing the least significant bits of the samples with “don't cares”, thereby generating at least one data word; addressing the memory with the at least one data word; receiving one or more addresses, said one or more addresses associated with one or more blocks; replacing a portion of the “don't cares” with a portion of the least significant bits of the samples, thereby generating another one or more data words; and addressing the memory with the another one or more data words.

In another embodiment, there is presented a video encoder for encoding a picture. The video encoder comprises a memory, a sampler, a register, and a bus. The memory stores a reference picture. The sampler takes samples from at least one line of a prediction block, wherein each of the samples comprises most significant bits and least significant bits. The register concatenates the samples and replaces the least significant bits of the samples with “don't care” indicators, thereby generating at least one data word. The bus addresses the memory with the at least one data word and provides one or more addresses, where the one or more addresses are associated with one or more blocks. The register replaces a portion of the “don't cares” with a portion of the least significant bits of the samples, thereby generating another one or more data words. The bus addresses the memory with the another one or more data words.

These and other advantages, aspects and novel features of the present invention, as well as details of illustrative aspects thereof, will be more fully understood from the following description and drawings.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a block diagram of exemplary pictures;

FIG. 2 is a flow diagram for encoding pictures in accordance with an embodiment of the present invention;

FIG. 3 is a block diagram of an exemplary video encoder in accordance with an embodiment of the present invention;

FIG. 4 is a block diagram describing the generation of a data word in accordance with an embodiment of the present invention;

FIG. 5 is a block diagram describing an exemplary reference picture stored in a memory in accordance with an embodiment of the present invention; and

FIG. 6 is a block diagram of an exemplary video encoder in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Referring now to FIG. 1, there is illustrated an exemplary prediction picture 10P and reference picture 10R. Video data comprises a series of pictures 10 that are captured at short time intervals, such as 1/24 sec, or 1/30 sec. When the pictures 10 are displayed on a display device at similar time intervals, the pictures simulate motion picture.

Motion compensation is a technique for encoding video data. Motion compensation takes advantage of the fact that pictures taken during proximate times, e.g., prediction picture P and reference picture R, are likely to contain many similarities. Moreover, the differences between the pictures are likely to be due to displacement of objects within the pictures.

Therefore, a picture, known as a prediction picture 10P, can be divided into blocks P, known as prediction blocks. The prediction blocks P can be encoded as a prediction error E. The prediction error E is a block that when added to a reference block R, yield the prediction block P. Where the reference block R and the prediction block P are similar, the prediction error E can either be nil, or small. Generally, smaller prediction errors require less data. Therefore, it is preferable to find a reference block R that is similar to the prediction block P.

Accordingly, the reference picture 10R is searched for blocks that are similar to blocks P. A reference block R is selected, and the prediction block P is represented by an identifier that identifies the reference block R and the prediction error E. The reference block is identified by a motion vector mv. A motion vector mv describes the displacement between the prediction block P and the reference block R. Finding the reference block R in the reference picture 10R is known as motion estimation.

Referring now to FIG. 2, there is illustrated a flow diagram for encoding video data in accordance with an embodiment of the present invention. At 205, a reference picture is stored in a memory. The memory can comprise, for example, a content addressable memory (CAM) or a tertiary CAM (TCAM).

At 210, samples are taken from one or more lines of the prediction block P. The prediction block comprises portions of a plurality of lines of the luma, chroma red, and chroma blue pixels of the pictures. In one embodiment, sampling the portion of the line can include selecting pixels at intervals from the portion, the intervals having a certain period, T.

Data word(s) are generated by concatenating the samples (at 215), and replacing (220) the least significant bits of the samples with “don't cares”. At 225, the memory is addressed with the data word(s). One or more addresses associated with one or more blocks are received at 227. The one or more blocks are potential reference blocks for the prediction block, and are likely to yield minimal prediction error for the prediction block.

To select a reference block from the potential reference blocks, at 230 the number of the don't cares in the data word(s) are reduced. The “don't cares” in the most significant bit positions are replaced by the corresponding least significant bits of the samples, thereby generating another data word(s).

The memory is addressed with data word(s) at 235, resulting in another set of addresses received at 240. The addresses received during 240 correspond to potential reference blocks that are a subset of the potential reference blocks during 227. However, the addresses received during 240 correspond to the potential reference blocks during 227 that are likely to yield even less prediction error for the prediction block. A particular reference block can be selected by repeating 230-240, until the addresses correspond to only one block at 245. At 250, the block is selected as the reference block.

Referring now to FIG. 3, there is illustrated a block diagram describing an exemplary video encoder 300 in accordance with an embodiment of the present invention. The video encoder 300 comprises a memory 305, a sampler 310, a register 315, a bus 320, and a comparator 325.

The memory 305 stores a reference picture. The memory can comprise, for example, a content addressable memory (CAM) or a tertiary CAM (TCAM). The sampler 310 takes samples from one or more lines of a prediction block P. The prediction block comprises portions of a plurality of lines of the luma, chroma red, and chroma blue pixels of the pictures. In one embodiment, the sampler 310 selects pixels at intervals from the one or more lines, the intervals having a certain period, T.

The register 315 generates data word(s) that are a function of the samples taken by the sampler 310. Each of the pixel samples taken by the sampler 310 include most significant bits and least significant bits. In one embodiment, the register 315 generates data words for each particular one of the one or more lines by concatenating the pixel samples from the particular line and replacing the least significant bits with what are known as “don't cares” X.

'Don't cares” indicate that the bits can either be a one “1” or zero “0”. The bus 320 uses the data word(s) generated by register 315 to address the memory and returns one or more addresses. The one or more addresses can be starting addresses from wherever the data word(s) are stored. Blocks can be formed starting from the addresses. These blocks are potential reference blocks for the prediction block P.

The register 315 progressively decreases the number of “don't cares” by replacing the “don't cares” in the most significant bit positions, with corresponding bits of the samples, thereby generating new data word(s). The bus 320 uses the new data word(s) to address the memory and returns address(es) from wherever the data word(s) are stored.

The addresses are a subset of the previous address(es). The blocks starting from the address(es) are also a subset of the previous potential reference blocks, but include the particular ones of the potential reference blocks that are likely to produce even less prediction error as a reference block.

The registers 315 and bus 320 can repeat the foregoing until the bus 320 returns address(es) corresponding to a single block. The single block is likely to produce the least prediction error, and is selected as the reference block.

Embodiments of the present invention will now be explained in the context of the MPEG-2 and H.264 standards. Of course, it shall be understood that the invention is not limited to these standards, and can be applied to other standards as well.

MPEG-2, H.264

Referring now to FIG. 4, there is illustrated a block diagram of a picture 100. A video camera captures pictures 100 from a field of view during time periods known as frame durations. The successive pictures 100 form a video sequence. A picture 100 comprises two-dimensional grid(s) of pixels 100(x,y).

For color video, each color component is associated with a two-dimensional grid of pixels. For example, a video can include a luma, chroma red, and chroma blue components. Accordingly, the luma, chroma red, and chroma blue components are associated with a two-dimensional grid of pixels 100Y(x,y), 100Cr(x,y), and 100Cb(x,y), respectively. When the grids of two dimensional pixels 100Y(x,y), 100Cr(x,y), and 100Cb(x,y) from the frame are overlayed on a display device, the result is a picture of the field of view at the frame duration that the frame was captured.

Generally, the human eye is more perceptive to the luma characteristics of video, compared to the chroma red and chroma blue characteristics. Accordingly, there are more pixels in the grid of luma pixels 100Y(x,y) compared to the grids of chroma red 100Cr(x,y) and chroma blue 100Cb(x,y). In the MPEG 4:2:0 standard, the grids of chroma red 100Cr(x,y) and chroma blue pixels 100Cb(x,y) have half as many pixels as the grid of luma pixels 100Y(x,y) in each direction.

The chroma red 100Cr(x,y) and chroma blue 100Cb(x,y) pixels are overlayed the luma pixels in each even-numbered column 100Y(x, 2 y) between each even, one-half a pixel below each even-numbered line 100Y(2 x, y). In other words, the chroma red and chroma blue pixels 100Cr(x,y) and 100Cb(x,y) are overlayed pixels 100Y(2 x+½, 2 y).

Encoding standards, such as MPEG-2 and ITU-H.264 (also known as MPEG-4, Part 10, and Advanced Video Coding, and now referred to as H.264) use motion compensation to encode and compress video data. Motion compensation divides the picture 100 into blocks, and encodes the blocks on the basis of a similar block that was previously encoded, known as a reference block.

For example, MPEG-2 uses what are known as macroblocks. The luma pixels of the frame 100Y(x,y), or top/bottom fields 110YT/B(x,y) can be divided into 16×16 pixel 100Y(16 x→16 x+15, 16 y→16 y+15) blocks 115Y(x,y). For each block of luma pixels 115Y(x,y), there is a corresponding 8×8 block of chroma red pixels 115Cr(x,y) and chroma blue pixels 115Cb(x,y) comprising the chroma red and chroma blue pixels that are to be overlayed the block of luma pixels 115Y(x,y). A block of luma pixels 115Y(x,y), and the corresponding blocks of chroma red pixels 115Cr(x,y) and chroma blue pixels 115Cb(x,y) are collectively known as a macroblock 120. In H.264, the macroblocks 120 can be further divided into 16×8, 8×16, 8×8, 4×8, 8×4, and 4×4 blocks 130.

In MPEG-2, each macroblock 120, is compared to the pixels of other pictures for a similar block of pixels P. In H.264, each block 130 is compared to the pixels of other pictures for a similar block of pixels R. The similar block of pixels is known as the reference block R. The difference between the macroblock 120 or block 130 and the reference block R is known as the prediction error E. The prediction error E is calculated and encoded, along with an identification of the reference block R. The reference block R is identified by motion vectors MV. Motion vectors MV describe the spatial displacement between the macroblock 120 or block 130 and the reference block R.

In MPEG-2 and H.264, the prediction error E is transformed to the frequency domain, and quantized. A minimal prediction error E is preferable because it takes fewer bits to encode. Accordingly, it is preferable that the reference block R and the macroblock 120 or block 130 are similar.

Motion Estimation for MPEG-2 and H.264

Referring now to FIG. 5, there is illustrated a block diagram describing data words 505 in accordance with an embodiment of the present invention. In the present example, the prediction block P is a macroblock 120 comprising 16×16 pixels. The prediction block P is sampled by selecting every fourth pixel in the horizontal direction and every fourth pixel in the vertical direction. Accordingly, the samples include:

-   -   120(0, 0), 120(0, 4), 120(0, 8), 120(0, 12) 120(4, 0), 120(4,         4), 120(4, 8), 120(4, 12) 120(8, 0), 120(8, 4), 120(8, 8),         120(8, 12) 120(12,0), 120(12,4), 120(12,8), 120(12,12)

For each sampled line, 0, 4, 8, 12, the samples are concatenated, forming concatenated words 510(0), 510 (1), 510(2), and 510(3). Each pixel is coded with a byte or eight bits. In the concatenated words 510, the four least significant bits for each concatenated sample are replaced with “don't cares”, X, thereby forming the data words 505(0), 505(1), 505(2), and 505(3).

Referring now to FIG. 6, there is illustrated a block diagram describing a reference picture stored in memory in accordance with an embodiment of the present invention. The memory is preferably, but not limited to, a TCAM memory. As noted above, the reference picture comprises luma, chroma red, and chroma blue components are associated with a two-dimensional grid of pixels 100Y(x,y), 100Cr(x,y), and 100Cb(x,y), respectively.

The luma pixels 100Y(x,y) from the reference picture are stored in a memory, such that each pixel is stored in memory consecutively with the fourth pixel in the horizontal direction, 100Y(x, y+4), where n=0, 1, 2, 3, . . . The lines of luma pixels are stored in the memory, in an order every line 100Y(x, - - - ) is stored following the fourth line above it 100Y(x−4, y). Accordingly, there will be sixteen sets of pixels, the pixels beginning from 100Y(0,0), . . . 100Y(0,3), 100Y(3,0), . . . 100Y(3,3).

Additionally, the byte address of a line 100Y(x, y) is offset from the byte address of the next line in the order, 100Y(x+4, y) by an integer power of two. For example, where the reference picture is a high definition television (HDTV) picture, in one current format, there are 1920 pixels in the horizontal direction. Accordingly, there will be 480 pixels in each line in a set. Therefore, the starting address of a line 100Y(x, - - - ) and the subsequently stored line 100Y(x+4, - - - ) can be offset by 512 bytes.

The data words 505(0), 505(1), 505(2), 505(3) are used to address the memory. Where the content of the memory matches the data words 505, the memory returns the starting byte addresses where the matching data word is stored.

The starting byte addresses returned for data word 505(0) indicate that line 0 of a block in the reference picture has pixels that are similar to the samples in the first line of the prediction block P.

The starting byte addresses returned for data word 505(1) indicates that line 4 of a block in the reference picture has pixels that are similar to the samples in the first line of the prediction block P.

The starting byte addresses returned for data word 505(2) indicate that line 8 of a block in the reference picture has pixels that are similar to the samples in the first line of the prediction block P.

The starting byte addresses returned for data word 505(3) indicate that line 12 of a block in the reference picture has pixels that are similar to the samples in the first line of the prediction block P.

As noted above, the byte address of a line 100Y(x, y) is offset from the byte address of the next line in the order, 100Y(x+4, y) by an integer power of two. Therefore, for each set of four addresses among the starting addresses returned for 505(0), 505(1), 505(2), and 505(3), where each are sequentially offset from each other by the integer power of two (i.e., the integer number of least significant bits are the same), the address for 505(0) is the starting address for a block that has pixels that are similar to all of the samples from the prediction block. The foregoing is a potential reference block.

Where there are multiple potential reference blocks, a single reference block from the multiple potential reference blocks can be narrowed down by progressively decreasing the number of don't cares in the data word(s) 505. According to certain aspects of the invention, when there are multiple potential reference blocks, the “don't care” in the most significant bit positions in the data word(s) can be replaced with corresponding bits of the samples. The new data word(s) 505 can then be used for addressing the memory. The foregoing can be repeated until the potential reference blocks are narrowed down to one reference block.

Referring now to FIG. 7, there is illustrated a block diagram describing an exemplary video encoder in accordance with an embodiment of the present invention. The video encoder encodes video data and comprises a motion estimator 705, a bus 706, TCAM memory 707, motion compensator 710, spatial predictor 715, transformation engine 720, quantizer 725, scanner 730, entropy encoder 735, inverse quantizer 740, and inverse transformation engine 745. The motion estimator 705, motion compensator 710, spatial predictor 715, transformation engine 720, quantizer 725, scanner 730, entropy encoder 735, inverse quantizer 740, and inverse transformation engine 745 can comprise hardware accelerator units under the control of a CPU.

When an input picture 100 _(n) is presented for encoding, the video encoder processes the picture loon in units of macroblocks 120 or blocks 130. The video encoder can encode each macroblock 120 or block 130 using temporal prediction. The motion estimator 705 and motion compensator 710 select a reference block R from one or more reference frames. Additionally, the motion estimator 705 and motion compensator 710 provide motion vectors identifying the reference block.

A subtractor 755 subtracts the prediction block P from the macroblock 120 or block 130 in frame F_(n), resulting in a prediction error E. Transformation engine 720 and quantizer 725 block transform and quantize the prediction error E, resulting in a set of quantized transform coefficients X. The scanner 730 reorders the quantized transform coefficients X. The entropy encoder 735 entropy encodes the coefficients. The video encoder also decodes the quantized transform coefficients X, via inverse transformation engine 745, and inverse quantizer 740, in order to reconstruct the frame F_(n) for encoding later other frames.

According to certain aspects of the present invention, the motion estimator 705 can comprise a sampler, and register as shown in FIG. 3. Additionally, in one embodiment of the present invention, the video encoder can operate as shown in FIG. 2.

The degree of integration of the encoder system will primarily be determined by speed and cost considerations. Because of the sophisticated nature of modern processor, it is possible to utilize a commercially available processor, which may be implemented external to an ASIC implementation. If the processor is available as an ASIC core or logic block, then the commercially available processor can be implemented as part of an ASIC device wherein certain functions can be implemented in firmware. Alternatively, the functions can be implemented as hardware accelerator units controlled by the processor.

While the present invention has been described with reference to certain embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the present invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the present invention without departing from its scope.

Therefore, it is intended that the present invention not be limited to the particular embodiment disclosed, but that the present invention will include all embodiments falling within the scope of the appended claims. 

1. A method for encoding a picture, said method comprising: a) storing a reference picture in a memory; b) taking samples from at least one line of a prediction block, wherein each of the samples comprises a plurality of bits, the plurality of bits comprising most significant bits and least significant bits; c) concatenating the samples; d) replacing the least significant bits of the samples with “don't cares”, thereby generating at least one data word; e) addressing the memory with the at least one data word; f) receiving one or more addresses, said one or more addresses associated with one or more blocks; g) replacing a portion of the “don't cares' with a portion of the least significant bits of the samples, thereby generating another one or more data words; and h) addressing the memory with the another one or more data words.
 2. The method of claim 1, wherein sampling further comprises: selecting pixels at intervals from the one or more lines, said intervals having a certain period.
 3. The method of claim 2, wherein storing the picture in the memory further comprises: storing pixels from one or more lines of the reference picture, such that pixels at intervals having the certain period are stored consecutively in the memory.
 4. The method of claim 1, further comprising: i) receiving another one or more addresses, said addresses associated with another one or more blocks.
 5. The method of claim 4, further comprising: repeating g)-i) until receiving only one or more addresses associated with only one block; selecting said block as a reference block for the prediction block.
 6. A video encoder for encoding a picture, said video encoder comprising: a memory for storing a reference picture; a sampler for taking samples from at least one line of a prediction block, wherein each of the samples comprises most significant bits and least significant bits; a register for concatenating the samples and replacing the least significant bits of the samples with “don't care” indicators, thereby generating at least one data word; a bus for addressing the memory with the at least one data word and providing one or more addresses, said one or more addresses associated with one or more blocks; wherein: a) the register replaces a portion of the “don't cares” with a portion of the least significant bits of the samples, thereby generating another one or more data words; and b) wherein the bus addresses the memory with the another one or more data words.
 7. The video encoder of claim 6, wherein the sampler selects pixels at intervals from the one or more lines, said intervals having a certain period.
 8. The video encoder of claim 7, wherein the memory stores pixels from one or more lines of the reference picture, such that pixels at intervals having the certain period are stored consecutively in the memory.
 9. The video encoder of claim 6, wherein: c) the bus provides another one or more addresses, said addresses associated with another one or more blocks.
 10. The video encoder of claim 9, wherein the register and bus repeat a)-c) until the bus provides another one or more addresses associated with only one block, said video encoder further comprising: a subtractor for generating a prediction error between the prediction block and the only one block. 